Synthesis of peptides in aqueous medium. VII. Preparation and use of

2,5-THIAZOLYDINEDIONES IN PEPTIDE

J. Org. Chem.,Vo1. 36,No. 1, lWl 49

SYNTHESIS

The Synthesis of Peptides in Aqueous Medium. VII. The Preparation and Use of 2,5-Thiazolidinediones in Peptide Synthesis R. S. DEWEY, E. F. SCHOENEWALDT, H. JOSHUA, WILLIAM3. PALEVEDA, JR.,H. SCHWAM, H. BARKEMEYER, BYRON H. ARISON,DANIELF. VEBER,R. G. STRACHAN, J. MILKOWSKI, ROBERTG. DENKEWALTER, AND RALPHHIRSCHMANN* Merck Sharp & Dohme Research Laboratories,Diwision of Mer& & Co., Xnc., Rahway, New Jersey 07065 Received May 4 IN0 Optically active N-thiocarboxyamino acid anhydrides, NTA’s (41, have been prepared and used for the stepwise synthesis of peptides in aqueous solution. Generally thiocarboxyanhydrides of good optical purity were obtained by the recrystallization of products from the reaction of alkoxythiocarbonyl L-amino acids (3) with phosphorus tribromide. Alternative syntheses of these anhydrides were provided by the cyclization of Iramino acid and I.-amino thio acid thio carbamates, or by the reaction of an bamino thio acid, Irthioproline, with phosgene. Salts of amino acid thiocarbamates were stable to electrophoresisa t pH 11, whereas the carbamate salts decamposed. Using conditions similar to those reported for N-carboxyanhydrides (NCA’s), addition of an NTA to ain aqueous solution of an amino acid or peptide at pH 9-9.5 a t No led to high yields of the peptide homolog. The increased stability of the thiocarbamates permitted the reaction to be carried out a t a lower pH than was the case with the NCA’s, generally affordinghigher yields but still leading to by-products analogous to those observed with the NCA’s. In contrast to the NCA’s, the NTA’s led to 1-20% of epimeric peptide in the product. Quantitation of small amounts of racemate derived from alanine NTA was made by nmr spectral comparison of the low intensity peaks in the alanine C-methyl doublet in a diastereomeric by-product with the ‘‘Csatellite peaks of the C-methyl doublet of the major product. Racemization occurring during reaction of proline NTA was estimated using a previously reported method in which the incorporation of tritium from labeled water was measured. The NTA’s which should prove most useful in peptide synthesis are those of glycine and alanine which gave significantly higher yields of product than the NCA’s, and histidine NTA which, in contrast to the NCA, was used successfully for controlled peptide synthesis.

The use of the a-amino acid N-carboxyanhydrides (NCA’s), 1, in the synthesis of peptides in aqueous solution is complicated by the fact that below pH 11the instability of peptide carbamates leads to overreactions via decarboxylation, whereas a t pH 11 overreaction uia the NCA anion, formation of hydantoic acids, and hydrolysis become troublesome side reactions. Hydantoic acid formation was a problem even at pH 10.2 with the NCA of glycine and occasionally with that of alanine. Further, histidine NCA rearranged t o a fused imidazolone. A more stable carbamate analog would permit peptide condensation to be carried out at lower pH and this, in turn, would suppress those side reactions arising from reactions of the anhydride with base. R/Ioreover, the production of a more stable carbamate ion should suppress the acid-catalyzed formation of overreaction products. It was thought that analogs of the NCA’s in which the ether oxygen is replaced by sulfur might solve some of these problems because the related thiocarbamates could be expected to show a greater stability a t a given pH than would the carbamates. A few free dithiocarbamic acids were known12and although the free monothiocarbamic acids had not been r e p ~ r t e dwe , ~ assumed that they would have a stability intermediate between the carbamates and dithiocarbamates. Therefore, it should be possible to carry out peptide syntheses a t a lower pH with NTA’s than with the NCA’s. The use of 2-thiono-5-i~hiazolidinones,2, in peptide synthesis has been reported, but a considerable amount of racemization accompanied peptide formation? The present 416

(1) R. Hirschmann, R. G. Strachan, H. Schwam, E. F. Schoenewaldt, H. Joshua, H. Barkemeyer, D. F. Veber, W. J. Paleveda, Jr., T. A. Jacob, T.E. Beesley, and R. G. Denkewalter, J. Org. Chem., $2, 3415 (1967). (2) (a) A. Y. Yakubovich and V. A. Klimova, J. Oen. Chem. USSR,9, 1777 (1939); Chem. Abstr., $4, 3685 (1940). (b) H. Korner, Chem. Ber., 41, 1901 (1908). (3) E. E. Reid, ”The Chemistry of Bivalent Sulfur,” Vol. IV, Chemical Publishing Co., New York, N. Y.,1962, p 196. (4) (a) J. D. Billimoria and A. H. Cook, J. Chem. Soc., 2323 (1949); (b) A. C. Davis and A. L. Levy, ibki., 2419 (1951). (5) A. H. Cook and A. L. Levy, ibid., 651 (1950).

1

2

paper describes the synthesis of optically active Nthiocarboxyanhydrides (NTA’s), ie., derivatives of 2,5thiazolidinedione (4, R = H), and their use in stepwise peptide synthesis in aqueous solutions! The N-thiocarboxyanhydride of glycine has been prepared by the reaction of the thionourethan, N-(ethoxythiocarbony1)glycine (3, R = H; R’ = Et), with phosphorus tribromide or tri~hloride.’-~ Recently, the syn-

L

3

5

4

(6) (a) For a preliminary communication, see R. S. Dewey, E. F. Schoenewaldt, H. Joshua, W. J. Paleveda, Jr., H. Schwam, H. Barkemeyer, B. H. Alison, D. F. Veber, R. G. Denkewzlter, and R. Hirschmann, J. Aner. Chem. Soc., SO, 3254 (1968). (b) We are grateful to Dr. Dieter Ziebarth of t h e Institute fur Xrebsforschung of the Deutsche Akademie der Wissenschaften zu Berlin for making available a copy of his recent thesis, “Uber 2,5-Dioxothiazolidine. Ein Beitrag zur Peptidsynthese,” Humbolt Universitlt, Berlin, 1968, in which he describes the preparation of Bome NTA’s and the formation of racemic peptides when the NTA’s were condensed in basic aqueous solution. (7) (a) P. Aubert and E. 3. Knott, Nature, 166, 1039 (1950); (b) P. Aubert, R. A. Jeffreys, and E. B. Knott, J . Chem. SOC.,2195 (1951). (8) J. L. Bailey, ibdd., 3461 (1950). 4 was formulated as the isomeric 2-thiono-5-oxazolone, i, a structure which was implicated in the formation of polyalanine by the thermal decomposition of lead alanine dithiocarbamate [G. Losse and H. Weddige, Justzls Liebigs Ann. Chem., 686, 144 (1960)l. 0

i (9) (a) H.G. Khorana, C h e m l n d . (London),129 (1951); (b) G. W. Kenner and H. 0.Khorana, J . Chem. Soc., 2076 (1952). Khorana proposed an NTA as a product in the acid cleavage of a peptide N-terminal alkoxuthiourethan.

50 J . Org. Chem., Vol. 36, No. 1, 1971

DEWEY, et al. TABLE I S

/I

N-(~KOXYTHIOCARBONYL) AMINOACIDS,ROCHNCHRCOaH Amino acid

R’ MP, “C

L-Ala

~-Alloisoleu

CHs 114-115

CHs 44-52

[CUI %9“ -19.3 -66 Calcd, % C 36.81 46.80 H 5.56 7.37 N 8.58 6.82 S 19.64 15.62 Found, % C 37.32 46.96 H 5.64 7.45 N 8.43 7.05 S 20.27 16.03 a c 1 (CHZCIZ) except as otherwise noted.

L-Are

Gly

&-His

CHs 212-220 dec

CHa 80-82

CzHs 212 dec +24

~-1leu

L-Leu

L-Phe

L-PI0

L-Val

CzHs 67-69

CHs 68-70

CzHs 85-88

CHs 93-94

CHs 63-66

+80.8

- 126b

-8.35

+15.9

-31.3

32.20 4.73 9.38

44.44 5.39 17.28 13.19

49.29 7.81 6.39 14.62

46.80 7.37 6.82 15.62

56.89 5.97 5.53 12.66

44.44 5.82 7.41 16.92

46.80 7.36 6.82 15.63

38.89 32.50 6.31 4.75 22.61 9.36 13.20 b c 1 (CHCls).

44.56 5.47 17.58 13.49

49.43 7.76 6.68 13.76

46.71 7.26 5.93 16.17

56.85 6.14 5.81 12.35

44 * 49 5.68 7.37 17.03

47.02 7.40 6.82 15.52

38.70 6.50 22.57 12.90

thesis of DL-phenylalanine NTA (4, R = CaH&H2) was reported. lo Glycine or m-alanine thioanhydride has been used to prepare glycylglycine ethyl ester,8 DL-alan y l g l y ~ i n e and , ~ ~ a glycine polymer. l1 The thioanhydride has also been postulated as the intermediate in the hydrogen chloride catalyzed cleavage of the N-terminal amino acid of a N-(ethoxythiocarbony1)peptide in analogy with the Edman d e g r a d a t i ~ n . ~ Greater stability of amino acid thiocarbamates compared to carbamates was indeed indicated by electrophoresis. The electrophoretic behavior of glycine carbamate12 (see below) a t pH 11 at room temperature is that of glycine indicating decomposition of the carbamate while glycine thiocarbamate moved with about twice the mobility of glycine indicating the greater stability of the thiocarbamate. Phenylalanine thiocarbamate showed a similar stability at pH 11,but when the electrophoresis was carried out a t pH 9 at room temperature streaking was observed, suggesting thiocarbamate decomposition during the electrophoresis a t the lower PH. Preparation of the NTA’s.-Because optically active NTA’s had not heretofore been prepared, a variety of methods were explored for the synthesis of NTA’s of L-amino acids. Of the methods outlined below, cyclization of the thionourethan 3 (method A) was the most convenient,’ and could in several instances be used to give material of good optical purity. Methods B and C also gave NTA’s of good optical purity, but the preparations involved more steps and led to lower yields, The peptides reported in this paper were synthesized with NTA’s prepared via method A unless otherwise specified. 1. Cyclization of N-Alkoxythiocarbonyl Amino Acids. Method A,-A number of optically active N-alkoxythiocarbonyl amino acids were prepared by the reaction of xanthate esters and L-amino acids in alcoholic base (Table I). Generally these derivatives could be crystallized except as noted. The optical purity of the N-alkoxythiocarbonyl derivatives of the amino acids (10) I. Z. Siemion, D. Konopidska, and A. Diugaj, Roc& Chem., 48, 989 (1969). (11) J. H. Bradbury and J. D. Leeder, Test. Res. J . , 80, 118 (1960); Chem. Abstr., 54, 8092d (1961). (12) A. C. Farthing, J . Chem. Soc., 3213 (1950).

was investigated in three cases. The preparation of N-ethoxythyocarbonylproline was carried out in ethanol-tritiated water. Examination of the recovered crystalline derivative for nonexchangeable tritium showed that less than 0.006% racemization had taken place. When N-(ethoxythiocarbony1)phenylalanine was treated with sodium methoxide in methanol under the conditions of synthesis, the optical rotation of the compound remained unchanged. Finally, repeated recrystallization of N-(ethoxythiocarbony1)-L-leucine as the quinine salt led to no change in rotation of the recovered compound. Therefore, the crystalline alkoxycarbonyl amino acids are thought to be of excellent optical purity. Aubert reported that alkoxythionocarbonylglycines (3, R = H) could be cyclized to the 2-alkoxy-bthiazolone 5 with acetic anhydride.la Application of this reaction to N-(methoxythiocarbony1)-L-leucine led to an oil which differed in its chromatographic behavior from both the thionourethan and the NTA. The infrared spectrum was consistent with the 5-thiazolone structure 5 (R = Me, R’ = i-Bu). Exposure of this oil to hydrogen chloride led to the formation of largely racemized leucine NTA. On the other hand, the rotation of phenylalanine NTA was essentially unchanged after treatment in T H F with hydrogen chloride or phosphorus trichloride for 1 hr a t room temperature. These results suggested that the racemization observed in the above leucine NTA occurred a t the intermediate 5-thiazolone stage. Indeed, the thiazolone 5 is analogous to the azlactones, which have been cited as a major pathway for racemization of N-acyl amino acid derivatives. l 4 Reaction of N-(methoxythiocarbony1)-L-leucine with phosphorus tribromide at -30” led to a mixture from which the related 5-thiazolone and a partially racemized NTA could be isolated by silica gel chromatography. The N-(alkoxythiocarbonyl) amino acids were best cyclized to the NTA’s 4 by reaction with phosphorus tribromide for 5-10 min at 0”. I n general, these conditions led to crystalline NTA’s of relatively high optical purity. Addition of nucleophiles,which should acceler(13) P. Aubert, E.E. Xnott, and L. A. Williams, ibid., 2185 (1951). (14) (a) J. P. Greenstein and M . Winitz, “Chemistry of the Amino Acids,” Vol. 11, Wiley, New York, N. Y., 1961,pp 832-836, and references therein; (b) I. Antonovics and G. T. Young, Chem. Commun., 398 (1965).

J . Org. Chem., Vol. 36,No. 1, 1971 51

2,5-THIA!ZOLIDINEDIONES I N PEPTIDES SYNTHESIS ate the cleavage of the intermediate oxazolone, such as sodium iodide, imidazole, or 1,2,4-triazole1l5 showed slight improvements in the yield and optical rotation of the NTA. Although Ihydrogen chloride in the previously cited experiment d.id not racemize a preformed NTA, treatment of NTA with hydrogen bromide a t room temperature led to a, drop in optical activity in the product. Nevertheless, the use of PBrs proved to be advantageous because the greater reactivity of phosphorus tribromide permitted NTA formation to be carried out for a shorter period of time, thus reducing exposure to acidic conditions. The overall advantage of the use of phosphorus tribromide may be attributed to the greater nucleophilic activity of brlomide ion in the cleavage of the thiazolone ether 5 . I n an attempt to circumvent some of the above probleins in the preparation of the NTA's, other methods of synthesis were examined. 2. From the Amino Acid Thiocarbamate. Method B.-Amino acid carbamates have been converted to NCA's with thionyl chloride.12 Reaction of phenylalanine with carbonyl sulfide in a basic medium led to the salt of the amino acid thiocarbamate (6, R = CaHr CH2).l6 Treatment of a suspension of this salt in tetrahydrofuran with phosphorus pentachloride gave a mix-

ture of phenylalanine NCA (1, R = CeH5CH2)and NTA (4, R = CeH5CH2). Addition of hydrogen sulfide rapidly cleaved the NCA, thus permitting the isolation of the unchanged NTA by extraction with ethyl acetate. The products had an optical purity comparable to those prepared by route A. 3. Other Routes.-The problem of contamination of the NTA with NCA in method B could be avoided by use of an amino thio acid. Optically active thioleucine was prepared from the NCA with hydrogen sulfide and then converted to the potassium salt of thioleucine thiocarbamate (7,R = i-Bu) in analogy to method B. The salt was cyclized directly in aqueous solution with Woodward's Reagent K to the NTA (method C). Alternatively, the amino thio acid thiophenylalanine was converted to the NTA of good optical purity with phosgene (method D) ,

+

RCHCOSK

COS

method D

KoH

RCHCOSK

Woodward's K

i-BuCHCONH2 RCHC0,H II *"

KOH

4- COS + RCHCOZK I

S

NHCOSK

8

6

4

!method B

4

1

(15) The addition of nucleophiles has catalyzed amino acid active ester condensations in some solvents: H. C. Beyerman and W. M. van den Brink, Proc. Chem. Soc., 266 (1963); T. Wieland and W. Kahle, Justus Liebigs Ann. Chem,, 691, 212 (1966). (16) An aqueous solution of phenylalanine thiocarbamate gave rise t o phenylalanine and a trace of phenylalanylphenylalanine on standing, which was detected by electrophoresis at p H 11. Upon tlc the dipeptide resolved into two spots corresponding t o LL- and Dt-phenylalanylphenylalanine. Phenylalanine carbamate did not give rise t o peptide formation under these conditions, whereas phenylalanine dithiocarbamate, which was prepared from phenylalanine, and carbon disulfide, did form the dipeptide. Further, a solution of phenylalanine thiocarbamate a n d radioactive phenylalanine in addition gave rise t o a ninhydrin negative spot on tlc corresponding t o hydantoic acid. A possible mechanism for the formation of these products is as follows. (H,O)'

+ RCHC0,I

H,NCHRCO;

+

COS

+

H20

NHCOS-

41

li

HS-

+ 17FHC01-

-0,CCHRNHCONHCHRCOL

I

N=C=O

11 H,NCHRCO,' -----+

dipeptide

This type of ring formation has been suggested previously by T. Wieland, R. Lambert, and H. U.Land, ibid., 697, 181 (1956). It may be noted that this route would seem t o offer another pathway t o peptide formation under prebiotic conditions.

Finally, in analogy with a known schemegfor peptide degradation, N-methoxythiocarbonylleucine amide (8) was cyclized to the NTA with hydrogen chloride (method E). The anhydride was, however, largely racemized. The results of these methods are outlined in Table 11. Optical Purity.-The optical purity of selected NTA's was estimated by hydrolysis to the amino acid and determination of the amount of the D isomer present in the product. I n general, the crystallization of the NTA's permitted the isolation of anhydrides with an optical purity 298%;. This was not true of the NTA of leucine. Rotations of samples of the latter varying from [ ~ 1 ] ~ ~ 5 8-30 9 t o -55" remained essentially unchanged upon crystallization. To determine the optical purity of the NTA of leucine, [aIb89-57.4"' a sample was treated with silver nitrate to give silver sulfide and leucine. The crude product was treated with phenylalanine NCA. The resulting dipeptide contained 3% LD isomer by comparison on tic" with dipeptide similarly prepared from DL-leucine and spotted at various concentrations. I n the case of the NTA of proline, acid hydrolysis gave a quantitative yield of proline. The crude reaction product was assayed with D-amino acid oxidase and was found to contain about 2% D-proline. Use of NTA's in Peptide Synthesis.-The reaction of N-thiocarboxyanhydrides with amino acids and peptides in aqueous solution was examined to determine yields and extent of racemization in peptide formation. The experimental conditions were similar to those used for the stepwise synthesis of peptides with NCA's,' (Scheme I) except that the p H was lower. After (17) E. Taschner, J. F. Biernat, and T. Sokolowski, Peptides, Proc. Bur. Sgmp., 5th, 1962 (1963).

52 J . Org. Chem., Vol. 36, No. 1, 1971

DEWEY, et al. TABLE I1

AMINO

Amino acid

Method

L-Ala0

Yield,

MP,

%

O C

ACIDN-THIOCARBOXYANHYDRIDES" C

[aI"saeb

H

Calod, % N

S

- -

C

H

Found, %-------N

S

A A A

47 91-93 -164 36.62 3.81 10.68 36.50 3.61 10.65 L-Argd 62.5 115-117 -124.5' 28.29 4.41 18.85 10.79 28.57 4.40 18.99 10.73 Glye 66 108-109 30.77 2.58 11.96 27.38 30.96 2.61 11.99 27.57 L-Hisd,e A 72.5 -7.Og 30.20 2.90 15.10 30.16 3.00 14.76 L-Leu A 68 77-78 -57.2 48.53 6.40 8.09 18.51 48.67 6.34 8.02 18.80 B 13 -56.0 c 45 76-77 -56.7 E 28 -34.5 L-Phee A 47 109-111 -154 57.94 4.37 6.75 15.46 58.10 4.31 6.67 15.70 B 25 111-112 -153 D 2gh 155, 154 L-Pro A 21 44.5-45 -157 45.80 4.55 8.96 20.40 45.96 4.43 8.90 19.71 L-Vale A 67 80-82 - 82 45.26 5.70 8.80 20.14 45.09 5.83 8.93 20.44 a The anhydrides were prepared from the methyl thionourethans unless otherwise indicated. c 1 (CHSC12) unless otherwise indicated. c Prepared in the presence of added imidazole. d As the N-thiocarboxyanhydride hydrobromide. 8 Prepared from the ethyl c 2 (methyl carbitol) a t 365 nm. thionourethan. f c 2 (DMSO). Two crops of 9.2 and 22%. i c 1 (CHCIa, EtOH free).

-

-

TABLE I11 PEPTIDES, PREPARED WITH NTA's IN COMPARISON WITH OTHERMETHODS --------Reactants---Car boxyanhydride

Nuoleophile

GlY GlY Ala Ala

Phe Phe-Leu Leu-Phe Ser-Val

His

Bel Phe- Asp- AlaSer-Val

-Isolated NTA,

pH--

7

NTA'"

NCAa

Produot

9.5 9.0 9.5 9.15

10.5 10.2 10.2 10.1

Gly-Phe Gly-Phe-Leu Ala-Leu-Phe Ala-Ser-Val

I

yield-? NCA,

%

%

93 75c 92 68d

50b 37 70 55d

I

Bel His-Phe- Asp- AlaSer-Val

9.0

I

24e

I

Bel Be1 Boc-His Ns Phe- Asp- AlaBoc-His-Phe- Asp79d Ser-Val' Ala-Ser-Val a The NCA or NTA was used in 10% excess unless otherwise specified. Disappearance yield. More than 20% of the hydantoic acid was indicated by tlc. 0 The NTA was used in 20% excess. Small amounts of impurities were indicated. 6 3.8 equiv of the NTA were used. f The reaction was run in DMF-Et20. J

SCHEMEI STEPWISESYNTHESIS OF PEPTIDES WITH NTA's R'CHC0,-

I

RCHCONH HI&OS9

4

R'CHCOZ-

2. -cos

I

RCHCONH

given in Table IV. The reactions were evaluated by paper-strip electrophoresis as previously described. A higher yield of peptide was obtained with the NTA a t pH 9.5 than with the NCA a t pH 10. Furthermore, the NTA left less unchanged arginine and afforded less of the overreaction product, Phe-Phe-Arg. The amount of hydantoic acid formed was not changed significantly. The yields in Tables I11 and IV support the expectation that a greater stability of the thiocarbamate should permit efficient peptide condensation to be carried out a t a lower pH.

I

N H,

TABLE IV REACTION PRODUCTS FROM PHENTA A N D PHENCA WITH LABELED ARGININE

10

cessation of a rapid uptake of base (2-30 min), the solution was acidified to cleave the carbonyl sulfide protecting group. The carbonyl sulfide was swept from the reaction mixture with nitrogen. Representative reactions of NTA's and NCA's with amino acid or peptide nucleophiles are compared in Table 111. The yields refer t o isolated products unless otherwise indicated. Alanine NTA and, especially, glycine NTA gave higher yields of the desired peptides than did the NCA's. A comparison of the products from the reaction of phenylalanine NCA and of NTA with 14C-arginine is

Reactants

Phe-NCA

+ W-Arg

PH, NTA

10.0

Yield,'

%

Product

Phe-Arg

89.2 3.5 Phe-Phe- Arg 4.0 Hydantoic acidb 2.8 Phe-NTA W-Arg 9.5 Phe-Arg 94.2 2.2 Phe-Phe- Arg 0.3 Hydantoic acidb 2.7 Yields based on radioactivity counts from fractions from paper electrophoresis. b HOzCCH (CH2C&)NHC0 Arg OH.

+

Q

-

2,5-THIAZOLI:DINEDIONESI N

PEPTIDES SYNTHESIS

A striking difference was noted between the NCA and the NTA of histidine. The former failed to yield histidy1 peptides a t pH 10.2, whereas the NTA was used, for example, t o prepare the C-terminal hexapeptide of ribonuclease18 (Table 111). Inspection of molecular models suggested that the imidazole nitrogen is in an ideal position to abstract the N H proton from the nitrogen of the anhydride ring. This intramoletular, basecatalyzed ring; opening which would lead to an isocyanate parallels the mechanism for isocyanate formation which had been proposed' to explain the hydantoic acid by-products in NCA reactions. I n the case of the NCA and NTA derived from histidine, the intermediate isocyanate can be expected to undergo further intramolecular reaction to form the imidazopyrimidine 11 (X = 0 or S, respectively), and indeed the NCA gave a noncrystalline product which was formulated as 11 (X = 0) on the basis of its ir and nmr spectra. When the NTA of histidine was treated with aqueous alkali a crystalline product was obtained after acidification which had an elemental analysis and ir spectrum consistent with structure 11 (X = S). An alternate structure, 12, was discarded on the basis of its infrared spectrum and of its expected ease of decarboxylation. We believe that the NTA, unlike the NCA, of histidine is useful in controlled peptide synthesis because the equilibrium be-

12

11

tween anhydride and isocyanate is shifted to the left when X = S. It was also possible to prepare histidyl peptides using compound 11 (X = S). The reaction proceeded slowly at room temperature but 11, unlike the NTA, failed t'o give histidyl peptides a t an appreciable rate at 0". In the reaction of glycine NTA with L-phenylalanyl5-leucine a 75% yield of the isolated tripeptide (Table 111) was obtained whereas the NCA gave about half that amount. I n Table V, the distribution of products PRODUCTS FROM

THE

TABLE V REACTION GLYCINENTA

WITH

II-PHENYLALANYL-~~C-L-LIOUCINE~

---yo---At E" Product

8.5

At pH 9.2

At p H 10.0

Gly-Phe-Leu 78.9 76.3 50.0 Hydantoic aoidb 5.95 5.55 5.15 Phe-Leu 12.28 11.64 33.7 Gly-Gly-Phe-Leu 3.03 6.33 8.47 (Gly)sPhe-Leu 0.07 0.34 2.14 a The reaction was carried out with a 5y0 deficiency of Gly NTA. b HSOCCH&HCO-Phe-Leu .OH. (18) S. R. Jenkins, R. F. Nutt, R. 8. Dewey, D. F. Veber, F. W . Holly, W. J. Paleveda, Jr., T.Lanaa, Jr., R. G. Strachan, E. F. Schoenewaldt, I€. Barkemeyer, M . J. Dickinson, S. Sondey, R. Hirschmann, a n d E. Walton, J . Amer. Chem. Soo., 9 1 , 505 (1969).

J. Org. Chem., Vol. 36, No. I , 1971

53

is shown for the reaction carried out between the 14Clabeled dipeptide used in 5y0 excess and glycine NTA. Altjhough the yield in NCA reactions decreases sharply when the reaction was carried out a t a pH below 10,' the NTA reaction is optimal either below the pH range studied or between 8.5 and 9.2 (see Table V). The data are consistent with the results expected for the greater stability of the thiocarbamate. Thus, overreaction is suppressed even a t pH 8.5 as judged by the lack of a substantial increase in the amount of unchanged nucleophile (Phe-Leu) indicating that it is not being inactivated by reaction with any carbonyl sulfide derived from the decomposition of the product thiocarbamate. The increase in residual nucleophile a t pH 10 can be ascribed to the loss of NTA via hydrolysis and polymerization. In the NCA reaction, the yield of hydantoic acid rose with pH.' I n the pH range examined for the NTA case (Table V), the yield of hydantoic acid remained essentially unchanged. That the NTA does form the anion is suggested by the increase in overreaction products a t high pH due to anionic oligomerization of the NTA. However, ring opening may be less favored for the reasons discussed in the case of NTA histidine. If it is assumed that the NTA has about the same solubility at the pH's studied and that the nucleophile competes relatively effectively against hydroxide ion for any isocyanate, a second mechanism for hydantoic acid formation may be required.lg I n stepwise peptide condensation, the NTA's gave a significant amount of the epimeric product,2o whereas the NCA's had given optically pure products. Using the NTA's in aqueous solutions, from less than 1 t o as high as 20% of the D isomer appeared in the resulting peptide. The reaction of L-histidine NTA hydrobromide with L-alanylglycine led to a mixture which was analyzed directly by nmr. The analysis of D-His-L-AlaGly in L-His-L-Ala-Gly could be made by comparison of the separated alanine methyl doublets of the two diastereomeric products using 100-MHz nmraZ1 The product contained 7575 of His-Ala-Gly, which consisted of 93% of the LL isomer and 6.7% of the DL isomer based on nmr examination of the freeze-dried crude product. Similarly, reaction of L-histidine NTA with D-alanylglycine gave a 58y0 yield of tripeptide, 83% of which was the LD isomer and 17% of which was the DD isomer. The (19) Possibly the hydantoic acid is formed by direct attack of the nucleophile on the carbamate carbonyl. Alternatively, the hydantoic acid could be formed via the isocyanate if the ring opening were catalyzed b y the solvent. (20) The late Professor Weygand had kindly offered the interesting suggestion t h a t the racemization might be attributed t o the presence of a 2thiono-5-oxazolone, i, as a n isomeric impurity in the NTA. Although me have no reference sample, two considerations argue against the presence of i in our cyclic anhydrides. It should be detectable by nmr or uv spectroscopy.

R A P

I

FIN